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Avoid inserting Result nodes that only compute identity projections.

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The planner sometimes inserts Result nodes to perform column projections
(ie, arbitrary scalar calculations) above plan nodes that lack projection
logic of their own.  However, we did that even if the lower plan node was
in fact producing the required column set already; which is a pretty common
case given the popularity of "SELECT * FROM ...".  Measurements show that
the useless plan node adds non-negligible overhead, especially when there
are many columns in the result.  So add a check to avoid inserting a Result
node unless there's something useful for it to do.

There are a couple of remaining places where unnecessary Result nodes
could get inserted, but they are (a) much less performance-critical,
and (b) coded in such a way that it's hard to avoid inserting a Result,
because the desired tlist is changed on-the-fly in subsequent logic.
We'll leave those alone for now.

Kyotaro Horiguchi; reviewed and further hacked on by Amit Kapila and
Tom Lane.
This commit is contained in:
Tom Lane 2013-03-14 13:42:51 -04:00
parent a5ff502fce
commit 4387cf956b
7 changed files with 163 additions and 128 deletions
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8
src/backend/optimizer/plan/createplan.c
View File

@ -937,10 +937,12 @@ create_unique_plan(PlannerInfo *root, UniquePath *best_path)
if (newitems || best_path->umethod == UNIQUE_PATH_SORT)
{
/*
* If the top plan node can't do projections, we need to add a Result
* node to help it along.
* If the top plan node can't do projections and its existing target
* list isn't already what we need, we need to add a Result node to
* help it along.
*/
if (!is_projection_capable_plan(subplan))
if (!is_projection_capable_plan(subplan) &&
!tlist_same_exprs(newtlist, subplan->targetlist))
subplan = (Plan *) make_result(root, newtlist, NULL, subplan);
else
subplan->targetlist = newtlist;

17
src/backend/optimizer/plan/planner.c
View File

@ -1379,10 +1379,12 @@ grouping_planner(PlannerInfo *root, double tuple_fraction)
{
/*
* If the top-level plan node is one that cannot do expression
* evaluation, we must insert a Result node to project the
* evaluation and its existing target list isn't already what
* we need, we must insert a Result node to project the
* desired tlist.
*/
if (!is_projection_capable_plan(result_plan))
if (!is_projection_capable_plan(result_plan) &&
!tlist_same_exprs(sub_tlist, result_plan->targetlist))
{
result_plan = (Plan *) make_result(root,
sub_tlist,
@ -1542,10 +1544,13 @@ grouping_planner(PlannerInfo *root, double tuple_fraction)
* If the top-level plan node is one that cannot do expression
* evaluation, we must insert a Result node to project the desired
* tlist. (In some cases this might not really be required, but
* it's not worth trying to avoid it.) Note that on second and
* subsequent passes through the following loop, the top-level
* node will be a WindowAgg which we know can project; so we only
* need to check once.
* it's not worth trying to avoid it. In particular, think not to
* skip adding the Result if the initial window_tlist matches the
* top-level plan node's output, because we might change the tlist
* inside the following loop.) Note that on second and subsequent
* passes through the following loop, the top-level node will be a
* WindowAgg which we know can project; so we only need to check
* once.
*/
if (!is_projection_capable_plan(result_plan))
{

37
src/backend/optimizer/util/tlist.c
View File

@ -158,6 +158,43 @@ get_tlist_exprs(List *tlist, bool includeJunk)
}
/*
* tlist_same_exprs
* Check whether two target lists contain the same expressions
*
* Note: this function is used to decide whether it's safe to jam a new tlist
* into a non-projection-capable plan node. Obviously we can't do that unless
* the node's tlist shows it already returns the column values we want.
* However, we can ignore the TargetEntry attributes resname, ressortgroupref,
* resorigtbl, resorigcol, and resjunk, because those are only labelings that
* don't affect the row values computed by the node. (Moreover, if we didn't
* ignore them, we'd frequently fail to make the desired optimization, since
* the planner tends to not bother to make resname etc. valid in intermediate
* plan nodes.) Note that on success, the caller must still jam the desired
* tlist into the plan node, else it won't have the desired labeling fields.
*/
bool
tlist_same_exprs(List *tlist1, List *tlist2)
{
ListCell *lc1,
*lc2;
if (list_length(tlist1) != list_length(tlist2))
return false; /* not same length, so can't match */
forboth(lc1, tlist1, lc2, tlist2)
{
TargetEntry *tle1 = (TargetEntry *) lfirst(lc1);
TargetEntry *tle2 = (TargetEntry *) lfirst(lc2);
if (!equal(tle1->expr, tle2->expr))
return false;
}
return true;
}
/*
* Does tlist have same output datatypes as listed in colTypes?
*

3
src/include/optimizer/tlist.h
View File

@ -25,6 +25,9 @@ extern List *flatten_tlist(List *tlist, PVCAggregateBehavior aggbehavior,
extern List *add_to_flat_tlist(List *tlist, List *exprs);
extern List *get_tlist_exprs(List *tlist, bool includeJunk);
extern bool tlist_same_exprs(List *tlist1, List *tlist2);
extern bool tlist_same_datatypes(List *tlist, List *colTypes, bool junkOK);
extern bool tlist_same_collations(List *tlist, List *colCollations, bool junkOK);

88
src/test/regress/expected/alter_table.out
View File

@ -385,61 +385,57 @@ create table nv_child_2011 () inherits (nv_parent);
alter table nv_child_2010 add check (d between '2010-01-01'::date and '2010-12-31'::date) not valid;
alter table nv_child_2011 add check (d between '2011-01-01'::date and '2011-12-31'::date) not valid;
explain (costs off) select * from nv_parent where d between '2011-08-01' and '2011-08-31';
QUERY PLAN
---------------------------------------------------------------------------------
Result
-> Append
-> Seq Scan on nv_parent
Filter: ((d >= '08-01-2011'::date) AND (d <= '08-31-2011'::date))
-> Seq Scan on nv_child_2010
Filter: ((d >= '08-01-2011'::date) AND (d <= '08-31-2011'::date))
-> Seq Scan on nv_child_2011
Filter: ((d >= '08-01-2011'::date) AND (d <= '08-31-2011'::date))
(8 rows)
QUERY PLAN
---------------------------------------------------------------------------
Append
-> Seq Scan on nv_parent
Filter: ((d >= '08-01-2011'::date) AND (d <= '08-31-2011'::date))
-> Seq Scan on nv_child_2010
Filter: ((d >= '08-01-2011'::date) AND (d <= '08-31-2011'::date))
-> Seq Scan on nv_child_2011
Filter: ((d >= '08-01-2011'::date) AND (d <= '08-31-2011'::date))
(7 rows)
create table nv_child_2009 (check (d between '2009-01-01'::date and '2009-12-31'::date)) inherits (nv_parent);
explain (costs off) select * from nv_parent where d between '2011-08-01'::date and '2011-08-31'::date;
QUERY PLAN
---------------------------------------------------------------------------------
Result
-> Append
-> Seq Scan on nv_parent
Filter: ((d >= '08-01-2011'::date) AND (d <= '08-31-2011'::date))
-> Seq Scan on nv_child_2010
Filter: ((d >= '08-01-2011'::date) AND (d <= '08-31-2011'::date))
-> Seq Scan on nv_child_2011
Filter: ((d >= '08-01-2011'::date) AND (d <= '08-31-2011'::date))
(8 rows)
QUERY PLAN
---------------------------------------------------------------------------
Append
-> Seq Scan on nv_parent
Filter: ((d >= '08-01-2011'::date) AND (d <= '08-31-2011'::date))
-> Seq Scan on nv_child_2010
Filter: ((d >= '08-01-2011'::date) AND (d <= '08-31-2011'::date))
-> Seq Scan on nv_child_2011
Filter: ((d >= '08-01-2011'::date) AND (d <= '08-31-2011'::date))
(7 rows)
explain (costs off) select * from nv_parent where d between '2009-08-01'::date and '2009-08-31'::date;
QUERY PLAN
---------------------------------------------------------------------------------
Result
-> Append
-> Seq Scan on nv_parent
Filter: ((d >= '08-01-2009'::date) AND (d <= '08-31-2009'::date))
-> Seq Scan on nv_child_2010
Filter: ((d >= '08-01-2009'::date) AND (d <= '08-31-2009'::date))
-> Seq Scan on nv_child_2011
Filter: ((d >= '08-01-2009'::date) AND (d <= '08-31-2009'::date))
-> Seq Scan on nv_child_2009
Filter: ((d >= '08-01-2009'::date) AND (d <= '08-31-2009'::date))
(10 rows)
QUERY PLAN
---------------------------------------------------------------------------
Append
-> Seq Scan on nv_parent
Filter: ((d >= '08-01-2009'::date) AND (d <= '08-31-2009'::date))
-> Seq Scan on nv_child_2010
Filter: ((d >= '08-01-2009'::date) AND (d <= '08-31-2009'::date))
-> Seq Scan on nv_child_2011
Filter: ((d >= '08-01-2009'::date) AND (d <= '08-31-2009'::date))
-> Seq Scan on nv_child_2009
Filter: ((d >= '08-01-2009'::date) AND (d <= '08-31-2009'::date))
(9 rows)
-- after validation, the constraint should be used
alter table nv_child_2011 VALIDATE CONSTRAINT nv_child_2011_d_check;
explain (costs off) select * from nv_parent where d between '2009-08-01'::date and '2009-08-31'::date;
QUERY PLAN
---------------------------------------------------------------------------------
Result
-> Append
-> Seq Scan on nv_parent
Filter: ((d >= '08-01-2009'::date) AND (d <= '08-31-2009'::date))
-> Seq Scan on nv_child_2010
Filter: ((d >= '08-01-2009'::date) AND (d <= '08-31-2009'::date))
-> Seq Scan on nv_child_2009
Filter: ((d >= '08-01-2009'::date) AND (d <= '08-31-2009'::date))
(8 rows)
QUERY PLAN
---------------------------------------------------------------------------
Append
-> Seq Scan on nv_parent
Filter: ((d >= '08-01-2009'::date) AND (d <= '08-31-2009'::date))
-> Seq Scan on nv_child_2010
Filter: ((d >= '08-01-2009'::date) AND (d <= '08-31-2009'::date))
-> Seq Scan on nv_child_2009
Filter: ((d >= '08-01-2009'::date) AND (d <= '08-31-2009'::date))
(7 rows)
-- Foreign key adding test with mixed types
-- Note: these tables are TEMP to avoid name conflicts when this test

110
src/test/regress/expected/inherit.out
View File

@ -1210,24 +1210,22 @@ select * from matest0 order by 1-id;
reset enable_indexscan;
set enable_seqscan = off; -- plan with fewest seqscans should be merge
explain (verbose, costs off) select * from matest0 order by 1-id;
QUERY PLAN
------------------------------------------------------------------------
Result
Output: matest0.id, matest0.name, ((1 - matest0.id))
-> Merge Append
Sort Key: ((1 - matest0.id))
-> Index Scan using matest0i on public.matest0
Output: matest0.id, matest0.name, (1 - matest0.id)
-> Index Scan using matest1i on public.matest1
Output: matest1.id, matest1.name, (1 - matest1.id)
-> Sort
Output: matest2.id, matest2.name, ((1 - matest2.id))
Sort Key: ((1 - matest2.id))
-> Seq Scan on public.matest2
Output: matest2.id, matest2.name, (1 - matest2.id)
-> Index Scan using matest3i on public.matest3
Output: matest3.id, matest3.name, (1 - matest3.id)
(15 rows)
QUERY PLAN
------------------------------------------------------------------
Merge Append
Sort Key: ((1 - matest0.id))
-> Index Scan using matest0i on public.matest0
Output: matest0.id, matest0.name, (1 - matest0.id)
-> Index Scan using matest1i on public.matest1
Output: matest1.id, matest1.name, (1 - matest1.id)
-> Sort
Output: matest2.id, matest2.name, ((1 - matest2.id))
Sort Key: ((1 - matest2.id))
-> Seq Scan on public.matest2
Output: matest2.id, matest2.name, (1 - matest2.id)
-> Index Scan using matest3i on public.matest3
Output: matest3.id, matest3.name, (1 - matest3.id)
(13 rows)
select * from matest0 order by 1-id;
id | name
@ -1258,48 +1256,45 @@ SELECT thousand, tenthous FROM tenk1
UNION ALL
SELECT thousand, thousand FROM tenk1
ORDER BY thousand, tenthous;
QUERY PLAN
-------------------------------------------------------------------------------
Result
-> Merge Append
Sort Key: tenk1.thousand, tenk1.tenthous
-> Index Only Scan using tenk1_thous_tenthous on tenk1
-> Sort
Sort Key: tenk1_1.thousand, tenk1_1.thousand
-> Index Only Scan using tenk1_thous_tenthous on tenk1 tenk1_1
(7 rows)
QUERY PLAN
-------------------------------------------------------------------------
Merge Append
Sort Key: tenk1.thousand, tenk1.tenthous
-> Index Only Scan using tenk1_thous_tenthous on tenk1
-> Sort
Sort Key: tenk1_1.thousand, tenk1_1.thousand
-> Index Only Scan using tenk1_thous_tenthous on tenk1 tenk1_1
(6 rows)
explain (costs off)
SELECT thousand, tenthous, thousand+tenthous AS x FROM tenk1
UNION ALL
SELECT 42, 42, hundred FROM tenk1
ORDER BY thousand, tenthous;
QUERY PLAN
------------------------------------------------------------------------
Result
-> Merge Append
Sort Key: tenk1.thousand, tenk1.tenthous
-> Index Only Scan using tenk1_thous_tenthous on tenk1
-> Sort
Sort Key: (42), (42)
-> Index Only Scan using tenk1_hundred on tenk1 tenk1_1
(7 rows)
QUERY PLAN
------------------------------------------------------------------
Merge Append
Sort Key: tenk1.thousand, tenk1.tenthous
-> Index Only Scan using tenk1_thous_tenthous on tenk1
-> Sort
Sort Key: (42), (42)
-> Index Only Scan using tenk1_hundred on tenk1 tenk1_1
(6 rows)
explain (costs off)
SELECT thousand, tenthous FROM tenk1
UNION ALL
SELECT thousand, random()::integer FROM tenk1
ORDER BY thousand, tenthous;
QUERY PLAN
-------------------------------------------------------------------------------
Result
-> Merge Append
Sort Key: tenk1.thousand, tenk1.tenthous
-> Index Only Scan using tenk1_thous_tenthous on tenk1
-> Sort
Sort Key: tenk1_1.thousand, ((random())::integer)
-> Index Only Scan using tenk1_thous_tenthous on tenk1 tenk1_1
(7 rows)
QUERY PLAN
-------------------------------------------------------------------------
Merge Append
Sort Key: tenk1.thousand, tenk1.tenthous
-> Index Only Scan using tenk1_thous_tenthous on tenk1
-> Sort
Sort Key: tenk1_1.thousand, ((random())::integer)
-> Index Only Scan using tenk1_thous_tenthous on tenk1 tenk1_1
(6 rows)
-- Check min/max aggregate optimization
explain (costs off)
@ -1345,16 +1340,15 @@ SELECT x, y FROM
UNION ALL
SELECT unique2 AS x, unique2 AS y FROM tenk1 b) s
ORDER BY x, y;
QUERY PLAN
-------------------------------------------------------------------
Result
-> Merge Append
Sort Key: a.thousand, a.tenthous
-> Index Only Scan using tenk1_thous_tenthous on tenk1 a
-> Sort
Sort Key: b.unique2, b.unique2
-> Index Only Scan using tenk1_unique2 on tenk1 b
(7 rows)
QUERY PLAN
-------------------------------------------------------------
Merge Append
Sort Key: a.thousand, a.tenthous
-> Index Only Scan using tenk1_thous_tenthous on tenk1 a
-> Sort
Sort Key: b.unique2, b.unique2
-> Index Only Scan using tenk1_unique2 on tenk1 b
(6 rows)
reset enable_seqscan;
reset enable_indexscan;

28
src/test/regress/expected/union.out
View File

@ -474,15 +474,14 @@ explain (costs off)
UNION ALL
SELECT * FROM t2) t
WHERE ab = 'ab';
QUERY PLAN
---------------------------------------------------
Result
-> Append
-> Index Scan using t1_ab_idx on t1
Index Cond: ((a || b) = 'ab'::text)
-> Index Only Scan using t2_pkey on t2
Index Cond: (ab = 'ab'::text)
(6 rows)
QUERY PLAN
---------------------------------------------
Append
-> Index Scan using t1_ab_idx on t1
Index Cond: ((a || b) = 'ab'::text)
-> Index Only Scan using t2_pkey on t2
Index Cond: (ab = 'ab'::text)
(5 rows)
explain (costs off)
SELECT * FROM
@ -510,10 +509,9 @@ explain (costs off)
UNION ALL
SELECT 2 AS t, * FROM tenk1 b) c
WHERE t = 2;
QUERY PLAN
---------------------------------
Result
-> Append
-> Seq Scan on tenk1 b
(3 rows)
QUERY PLAN
---------------------------
Append
-> Seq Scan on tenk1 b
(2 rows)